Using extra space on ultra high defintion display presenting high defintion video

ABSTRACT

A UHD display presents HD video in the native resolution of HD, leaving some portions of the UHD display unused for presenting the HD video. Ancillary information received, for example, in real time with the HD video or in parallel with the HD video over the Internet is presented in the unused portions of the UHD display along with the HD video.

FIELD

The present application relates generally to using extra space on ultrahigh definition (UHD) displays when the UHD displays present highdefinition (HD) video.

BACKGROUND

High Definition (HD) displays have been introduced which have greaterresolution than standard definition (SD) displays. This is achieved byincreasing the pixel density from the standard 640 or 720 pixels perline, with 480 lines (720×480), to the HD 1920×1080 (for progressive andinterlaced scans) 1440×1080 (for older interlaced scans). The greaterresolution produces a clearer, more detailed visual presentation.

Recently, ultra high definition (UHD) displays have been introduced witheven greater resolution than HD. As understood herein, owing to thepaucity of programming available for UHD, current UHD displays presentHD video which is simply upscaled to fill the entire display. Thisapproximation to true UHD, however, may undesirably cause imageartifacts to appear. As understood herein, there are more advantageousways to exploit the improved capability of UHD displays.

SUMMARY OF THE INVENTION

An assembly includes an ultra high definition (UHD) display configuredfor presenting video in 2160 pixel lines or 4320 pixel lines and aprocessor configured for controlling the UHD display. The assembly alsoincludes a computer readable storage medium bearing instructionsexecutable by the processor to: present high definition (HD) video onthe UHD display using at least 1440 of the pixel lines, wherein portionsof the display do not present HD video when HD video is being presentedelsewhere on the display. In addition, the instructions are executableby the processor to present ancillary information in the portions of thedisplay that do not present HD video. The ancillary information isreceivable from a source of TV signals or from the Internet in real timewith the HD video.

The processor when executing the instructions presents the HD video mayuse at least 1920 lines of the UHD display. The ancillary informationcan be received from the source of TV signals along with the HD video ina common channel with the HD video or it may be received from theInternet.

A user input device can be configured for communicating with theprocessor to input first and second user commands. The first usercommand may be to present the HD video on the entire UHD display byupscaling the HD video and the second user command may be to present theHD video on a portion of the UHD display and to present on the UHDdisplay the ancillary information along with the HD video. The ancillaryinformation can be configured for being ignored by non-UHD assemblies.

In another aspect, a method includes receiving, at an ultra highdefinition (UHD) display characterized by a first resolution, highdefinition (HD) video characterized by a second resolution less than thefirst resolution. The method also includes presenting the HD video onthe UHD display without upscaling the HD video to fill the entire UHDdisplay to thereby render portions of the UHD display that do notpresent the HD video. Furthermore, the method includes presentingancillary information in the portions of the UHD display that do notpresent the HD video.

In another aspect, an ultra high definition (UHD) display deviceincludes a UHD display configured for presenting non-UHD video in anative resolution of the non-UHD video, leaving some portions of the UHDdisplay unused for presenting non-UHD video to establish unused displayportions. A processor is included in the UHD display device and isconfigured for controlling the UHD display to present demanded images.The processor is configured for causing ancillary information receivedin real time with the non-UHD video or in parallel with the non-UHDvideo over the Internet to be presented in the unused display portionsof the UHD display along with the non-UHD video.

The details of the present invention, both as to its structure andoperation, can best be understood in reference to the accompanyingdrawings, in which like reference numerals refer to like parts, and inwhich:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of a non-limiting example system in accordancewith present principles;

FIG. 2 is a block diagram of an example TV;

FIG. 3 is a screen shot of an example user interface (UI) that can bepresented on the UHD display to allow a user to enable upscaling ofvideo such as SD or HD video to fill the UHD display or to present thevideo in its native resolution, filling in unused display areas withancillary information;

FIG. 4 is a schematic diagram of an example data structure the header ofwhich is readable by UHD displays but not by HD displays;

FIG. 5 is a flow chart of example logic;

FIG. 6 is a flow chart of additional example logic; and

FIG. 7 is a screen shot of a UHD display presenting HD video in nativeHD video resolution and presenting ancillary information in unusedportions of the UHD display.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring initially to the non-limiting example embodiment show in FIG.1, a system 10 includes an audio video device such as a TV 12 includinga TV tuner 16 communicating with a TV processor 18 accessing a tangiblecomputer readable storage medium 20 such as disk-based or solid statestorage. The TV 12 can output audio on one or more speakers 22. The TV12 can receive streaming video from the Internet using a built-in wiredor wireless modem 24 communicating with the processor 12 which mayexecute a software-implemented browser 26. Video is presented undercontrol of the TV processor 18 on a TV display 28 which according topresent principles is an ultra high definition (UHD) display such as aflat panel display. The display 28 may be a 2160p (progressive scan)display with a resolution of 3840×2160 pixels (for 4K UHD) or 4320p(progressive scan) display with a resolution of 7860×4320 pixels (for 8KUHD). Frame rates for the UHD display 28 can be 24, 25, 50, 60, or 120frames per second.

User commands to the processor 18 may be wirelessly received from aremote control (RC) 30 using, e.g., rf or infrared. Audio-video displaydevices other than a TV may be used, e.g., smart phones, game consoles,personal digital organizers, notebook computers and other types ofcomputers, etc.

TV programming from one or more terrestrial TV broadcast sources 32 asreceived by a terrestrial broadcast antenna 34 which communicates withthe TV 12 may be presented on the display 28 and speakers 22. Theterrestrial broadcast programming may conform to digital ATSC standardsand may carry within it a terrestrial broadcast EPG, although theterrestrial broadcast EPG may be received from alternate sources, e.g.,the Internet via Ethernet, or cable communication link, or satellitecommunication link.

TV programming from a cable TV head end 36 may also be received at theTV for presentation of TV signals on the display 28 and speakers 22.When basic cable only is desired, the cable from the wall typicallycarries TV signals in QAM format and is plugged directly into the“F-type connector” 38 on the TV chassis in the U.S., although theconnector used for this purpose in other countries may vary. Incontrast, when the user has an extended cable subscription for instance,the signals from the head end 36 are typically sent through a STB 40which may be separate from or integrated within the TV chassis but inany case which sends HDMI baseband signals to the TV.

Similarly, HDMI baseband signals transmitted from a satellite source 42of TV broadcast signals received by an integrated receiver/decoder (IRD)44 associated with a home satellite dish may be input to the TV 12 forpresentation on the display 28 and speakers 22. Also, streaming videomay be received from the Internet 46 for presentation on the display 28and speakers 22. The streaming video may be received at the computermodem 24 or it may be received at an in-home modem 48 that is externalto the TV 12 and conveyed to the TV 12 over a wired or wireless Ethernetlink and received at an RJ45 or 802.11x antenna on the TV chassis.

FIG. 2 shows details of an example TV 12. As shown, the terrestrialsignal in ATSC format is input to the TV tuner 16, as is basic cable inNTSC or QAM format in the event that basic cable is used and the wallcable plugged into the F-type connector 38. On the other hand, streamingInternet video may be received at a DOCSIS tuner 50 anddemodulated/decoded at a DOCSIS decoder/demodulator 52. Typically, theDOCSIS components are housed separately from the TV 12 but in someembodiments may be included in the chassis of the TV 12.

The output of the tuner 16, depending on the signal format received, maybe sent to an appropriate decoder/demodulator 58 the output of whichtypically is sent to a transport stream demultiplexer 60, whichseparates the desired program from other programs in the selected streamand sends the desired program to an MPEG video decoder 62, which in turnuncompresses the MPEG desired program and sends the uncompressed programto the TV display 28 for presentation. Audio from the demultiplexer 60may be sent to an audio decoder 64 which in turn sends the decoded audioto the speakers 22 for presentation.

In contrast to the sequence of decoder/demodulators, demultiplexer, andMPEG decoders discussed above, video from either the STB 40 or IRD 44 isin baseband HDMI when it is received by the TV 12. Accordingly, thesignals from the STB 40 or IRD 44 are sent directly to the TV display 28for presentation without further video decompression between the STB 40or IRD 44 and TV display 28. Audio from the STB 40 or IRD 44 may stillbe in a format, e.g., AC3, that requires decoding prior to play on thespeakers 22 so the audio may be sent through the audio decoder 64 asshown. Likewise, audio from the ATSC terrestrial source 32 may be in AC3format and so may be sent through the audio decoder 64. Internet videofrom the DOCSIS decoder/demodulator 52 may be sent through thedemultiplexer 60 and decoders 62, 64 as shown.

Now referring to FIG. 3, an example user interface is shown on the UHDdisplay 28. In the case of the TV 12 receiving HD data from any sourcedescribed above, the user may select (using the remote control 30) afirst user command 66 to upscale the HD video and fill the UHD display28 with the HD video. Upscaling matches the pixel count of the HD videoto the greater pixel count of the UHD display by, e.g., interpolatingtwo adjacent pixel values in the HD and inserting an extra pixel betweenthem with the interpolated value. The user can alternatively select asecond user command 68 and present ancillary information rather thanupscaling the HD video to fill the display 28. In this case, theprocessor 18 can present the HD video on the UHD display 28 using atleast 1440 of the pixel lines, leaving portions of the display 28unused. The processor 18 may present ancillary information in the unusedportions of the display 28. The ancillary information can be receivedfrom a source of TV signals or from the Internet 46 in real time withthe HD video.

Moving in reference to FIG. 4, the data structure for HD video withancillary information is illustrated. A header 70 is attached toancillary information 72 and HD video 74 and is recognized only by UHDdisplays. Examples of ancillary information 72 can be, but are notlimited to, statistics for sporting events, additional advertising suchas a sponsor's logo, interactive games while watching game shows, etc.The broadcast TV source 32 may send HD video 74 with the header 70 andconsequently cause the processor 18 to prompt the user of the UHDdisplay 28 with the UI in FIG. 3.

FIG. 5 diagrams a first flow of logic beginning at block 76, wherein thebroadcast TV source 32 may embed ancillary data for UHD displays intotheir stream (ATSC, MPEG, etc). It is determined at decision diamond 78whether the receiving display device 12 is capable of UHD resolution. Inone example this can be done by determining whether the processor 18 isable to read the header 70 of FIG. 4. If the display device 12 is notcapable of UHD resolution, and therefore does not recognize the header70, the device 12 ignores the ancillary content 72 at block 80.Alternatively, if the display device 12 is capable of UHD resolution,and therefore recognizes the header 70, the flow of logic moves to FIG.6.

The second flow of logic in FIG. 6 begins at block 82, wherein theprocessor 18 receives the user selection from the user interface in FIG.3. If the user input indicates full screen presentation of video atdecision diamond 84, the HD video undergoes upscaling to fill the entireUHD display 28 at block 86. A user input indicating less than fullscreen presentation moves logic to block 88, at which point the HD videois presented on the UHD display 28 at normal HD size, leaving blankportions of the display 28. Ancillary information is presented in realtime along with the broadcasted content in unused portions of thedisplay 28 at block 90.

Ancillary information is not limited to content sent by the broadcaster.The ancillary information displayed at block 90 may come in the form ofInternet browsing or an interactive application. Or, the ancillaryinformation may come from intermediaries such as a business who wants toshowcase their own products. In an example embodiment, a sports barcarrying live games can display their menu or drink specials in realtime around the HD broadcast.

The screen shot in FIG. 7 illustrates some examples of creative uses ofunused portions of the display 28. HD broadcast content 92 is presentedin standard HD size and clearly does not fill the entire display 28 butrather just a portion. In this embodiment, an advertisement 94 and anews crawl or other information/text 96 are displayed on the unusedportions of the display 28.

A standard can be developed specifically for UHD displays to interpretdata from a MPEG2 or MPEG4/AVC stream that allows it to use the extraresolution space. This can also be applied to Blu-ray discs or onlinevideo streaming services as well. This allows it to maintain backwardscompatibility with existing 1920×1080 displays which would simply ignorethe UHD related data.

While the particular USING EXTRA SPACE ON ULTRA HIGH DEFINITION DISPLAYPRESENTING HIGH DEFINITION VIDEO is herein shown and described indetail, it is to be understood that the subject matter which isencompassed by the present invention is limited only by the claims. Forexample, present principles may be incorporated into a smart phone suchthat various behavior as would be reflected by a recognized sound wouldtrigger recording into the phone as a “life log”.

What is claimed is:
 1. Assembly comprising: ultra high definition (UHD)display configured for presenting video in 2160 pixel lines or 4320pixel lines; processor configured for controlling the UHD display; abrowser that is executed by the processor; and computer readable storagemedium bearing instructions executable by the processor to: present highdefinition (HD) video on the UHD display using at least 1440 of thepixel lines, wherein portions of the display do not present HD videowhen HD video is being presented elsewhere on the display; and presentancillary information in the portions of the display that do not presentHD video, the ancillary information being receivable from a source of TVsignals or from the Internet in real time with the HD video.
 2. Theassembly of claim 1, wherein the processor when executing theinstructions presents the HD video using at least 1920 lines of the UHDdisplay.
 3. The assembly of claim 1, wherein the ancillary informationis received from the source of TV signals along with the HD video in acommon channel with the HD video.
 4. The assembly of claim 1, whereinthe ancillary information is received from the Internet.
 5. The assemblyof claim 1, comprising a user input device configured for communicatingwith the processor to input first and second user commands, the firstuser command being to present the HD video on the entire UHD display byupscaling the HD video, the second user command being to present the HDvideo on a portion of the UHD display and to present on the UHD displaythe ancillary information along with the HD video.
 6. The assembly ofclaim 1, wherein the ancillary information is configured for beingignored by non-UHD assemblies.
 7. Method comprising: receiving, at anultra high definition (UHD) display characterized by a first resolution,high definition (HD) video characterized by a second resolution lessthan the first resolution; presenting the HD video on the UHD displaywithout upscaling the HD video to fill the entire UHD display to therebyrender portions of the UHD display that do not present the HD video; andpresenting ancillary information in the portions of the UHD display thatdo not present the HD video.
 8. The method of claim 7, wherein the UHDdisplay presents video in 2160 pixel lines or 4320 pixel lines and theHD video uses at least 1440 of the pixel lines on the UHD display. 9.The method of claim 7, wherein the HD video uses at least 1920 lines ofthe UHD display.
 10. The method of claim 7, comprising receiving theancillary information from a source of TV signals along with the HDvideo in a common channel with the HD video.
 11. The method of claim 7,comprising receiving the ancillary information from the Internet. 12.The method of claim 7, comprising receiving from a user input devicefirst and second user commands, the first user command being to presentthe HD video on the entire UHD display by upscaling the HD video, thesecond user command being to present the HD video on a portion of theUHD display and to present on the UHD display the ancillary informationalong with the HD video.
 13. The method of claim 7, wherein theancillary information is configured for being ignored by non-UHDassemblies.
 14. An ultra high definition (UHD) display devicecomprising: a UHD display configured for presenting non-UHD video in anative resolution of the non-UHD video, leaving some portions of the UHDdisplay unused for presenting non-UHD video to establish unused displayportions; a processor configured for controlling the UHD display topresent demanded images, the processor configured for causing ancillaryinformation received in real time with the non-UHD video or in parallelwith the non-UHD video over the Internet to be presented in the unuseddisplay portions of the UHD display along with the non-UHD video; and abrowser that is executed by with the processor.
 15. The device of claim14, wherein the ancillary information is received from a source of TVsignals along with the non-UHD video in a common channel with thenon-UHD video.
 16. The device of claim 14, wherein the ancillaryinformation is received from the Internet.
 17. The device of claim 14,comprising a user input device configured for communicating with theprocessor to input first and second user commands, the first usercommand being to present the non-UHD video on the entire UHD display byupscaling the non-UHD video, the second user command being to presentthe non-UHD video on a portion of the UHD display and to present on theUHD display the ancillary information along with the non-UHD video. 18.The device of claim 14, wherein the ancillary information is configuredfor being ignored by non-UHD assemblies.